

��

Vol. 45. No. 1 March 2012

Research Report

Crude toxin of Aggregatibacter actinomycetemcomitans  
serotype-B increase PARP-� expression in gingival epithelium

Ernie Maduratna Setiawatie
Department of Periodontics/Institute of Tropical Disease, Airlangga University 
Faculty of Dentistry, Airlangga University 
Surabaya - Indonesia

abstract

Background: Aggregatibacter actinomycetemcomitans (A. actinomycetemcomitants) serotype-B has long been associated with 
aggressive periodontitis. Gingival epithelial cell is exquisitely sensitive to the toxin so that may lead to disruption of the epithelial 
protective barrier, facilitating invasion and perturbation of the underlying connective tissue. Currently suggested that Aa serotype-
B produce protein toxin that caused DNA strand breaks. PARP-1 is an abundant nuclear protein functioning as a DNA nick-sensor 
enzyme. PARP-1 was one of the first identified substrates of caspases, the main executioners of apoptosis. Therefore, a role for PARP-1 
in the regulation of apoptosis has been suggested. Purpose: The purpose of this study was to prove PARP-1 expression in gingival 
epithelium caused by toxin exposure of A. actinomycetemcomitant serotype-B. Methods: This is an experimental study involving twenty 
adult mice strain Swiss Webster (balb C) divided randomly into two groups: control group (Group A) and toxin group (Group B). Both 
group were acclimated for one week before treatment. Group A was applied topically with sterile distillated water every 12 hours. 
Group B was applied topically by 100μg/ml of crude toxin A. actinomycetemcomitant serotype B at the buccal area of mandibular 
anterior teeth using Hamilton syringe. The mice were sacrificed at 24 hours after toxin application, and then the tissue sections of 
gingival epithelium were stained with immunohistochemistry to reveal the PARP-1 expression. The data were analyzed with t-test. 
results: The PARP-1 expression exhibited an increase with the toxin group (mean= 48.9; SD= 2.01) compared with the control group 
(mean= 25.21; SD= 1.72). DNA fragmentation appeared from the agarose gel examination, marked as DNA laddering, indicate the cell 
apoptosis. Conclusion: In conclusion the crude toxin exposure of A. actinomycetemcomitant serotype-B leads to DNA fragmentation 
and increase PARP-1 expression.

Key words: Crude toxin of Aggregatibacter actinomycetemcomitans serotype-B, PARP-1, DNA fragmentation 

abstrak

latar belakang: Aggregatibacteractinomycetemcomitans (A. actinomycetemcomitant) serotype-B merupakan etiologi utama 
periodontitis agresif. Sel epitel gingiva sangat sensitif terhadap toksin sehingga dapat mengganggu epitel sebagai pertahanan 
awal gingiva, membantu invasi toksin dan mengganggu jaringan ikat dibawahnya. Saat ini diketahui bahwa toksin bakteri Aa 
serotype-B menyebabkan putusnya rantai DNA. PARP-1 merupakan protein dalam intisel yang berfungsi sebagai DNA nick-
sensor enzyme. PARP-1 merupakan penanda awal apoptosis, sehingga peran PARP-1 dalam pengaturan apoptosis perlu diteliti 
tujuan: Tujuan dari penelitian ini adalah untuk meneliti ekspresi PARP-1 pada epitel gingiva yang dipapar toksin bakteri 
A. actinomycetemcomitant serotype-B. Metode: Penelitian eksperimen pada 20 mencit strain Swiss Webster (balb C) dibagi 
secara random dalam 2 kelompok, kelompok kontrol (Group A) dan kelompok perlakuan (Group B). Kedua kelompok diaklimasi 
sebelumnya selama 1 minggu. Kelompok diaplikasi secara topikal dengan air destilasi steril setiap 12 jam. Kelompok B diaplikasi  
100 μg/ml toksin A. actinomycetemcomitant serotype-B secara topikal dengan menggunakan Hamilton syringe. Mencit dimatikan 24 
jam setelah aplikasi toksin kemudian potongan epitel gingiva dilakukan pemeriksaan secara imunohistokimia untuk melihat ekspresi 
PARP-1. Data dianalisis dengan uji-t hasil: Ekspresi PARP-1 menunjukkan penigkatan pada kelompok perlakuan (Mean = 48,9; SD =  
2,01) bila dibanding kelopok kontrol (Mean= 25,21; SD= 1,72). Tampak adanya gambaran DNA fragmentasi pada pemeriksaan gel 
elektroforesis yang menunjukkan adanya apoptosis. Kesimpulan: Dapat disimpulkan bahwa paparan toksin A. actinomycetemcomitant 
serotype-B menyebabkan DNA fragmentasi, dan meningkatkan ekspresi PARP-1. 


�0 Dent. J. (Maj. Ked. Gigi), Vol. 45. No. 1 March 2012: 39–42

introduction

Aggressive periodontitis is a form of periodontal disease, 
which has a sign of aggressive destruction of periodontal 
ligament and alveolar bone. The loss of attachment is three 
times higher than chronic periodontitis causing premature 
tooth loss. The prevalence of aggressive periodontitis can 
reach a significant number of 10 to 15 percent.1 The trigger 
of aggressive periodontitis is the predominant specific 
bacterium of Aggregatibacter actinomycetemcomitans 
(A. actinomycetemcomitant) serotype-B.2 The bacterium 
and its end-products can interact with gingival epithelium 
during the chronic infection, furthermore will penetrate 
into fibroblast, periodontal ligament and alveolar bone. 
A. actinomycetemcomitans inhibits the proliferation 
and supporting the apoptosis of gingival cell, fibroblast, 
osteoblast, macrophage, lymphocyte B and lymphocyte 
T.3,4 

 Apoptosis plays an important role in the homeostasis of 
cells and tissue in response to damage. PARP-1-mediated 
poly (ADP-ribosylation) of nuclear proteins is required 
for apoptosis. During apoptosis, caspase-7 and caspase-3 
cleave PARP-1 into two fragments: p89 and p24.5 PARP-1 
also plays a central role in a caspase-independent apoptosis 
pathway mediated by apoptosis-inducing factor (AIF). 
The induction of apoptosis at the host cell triggered by 
specific pathogenic bacterium is a new phenomenon in 
the pathogenesis of periodontal diseases.6 The incidence of 
apoptosis at the underlying gingival pocket epithelium can 
be continuously occur and can caused further destruction 
by decreased fibroblasts, diminished lymphocytes 
functions and declined osteoblast. If it occurs, tooth 
will lose its attachment to periodontium and will cause 
premature tooth detachment and loss.7 The gingival cell 
acts as the port d’entrée of A. actinomycetemcomitans 
into the periodontium, thus taking part in the development 
of inflammation and the progressivity of periodontal 
disease. This research is aimed to examine of PARP-I 
expression in gingival epithelium that exposed to A. 
actinomycetemcomitant serotype-B toxin.

materials and methods

This experimental research was using male rat 
(Musmusculus strain Swiss Webster balb c). The 
methodology was using post test only group design. The 
analysis unit was gingival epithelial cell of the bucco-
anterior rat mandible, physically fit, aged at 2.5 months 
with body weight of 25–35 gram obtained from Pharma 
Veterinary Centre Surabaya. First treatment (control 
group): ten rats were given sterile distillated water topically 

at the bucco-anterior mandibular gingiva every twelve 
hours with aid from disposable oral sponge swab (Rynell 
Inc, USA) immersed into sterile distillated water until 
thoroughly wet, then applied with double lateral strokes. 
Second treatment (treatment group): ten rats were applied 
topically with A. actinomycetemcomitans serotype-B toxin 
at 100µg/ml at the bucco-anterior mandibular gingiva using 
Hamilton syringe (Reno, Nevada USA). After twenty-four 
hours, the rats were eliminated and the mandibular gingiva 
were incised as biopsy specimen. 

The immunohistochemistry examination with the 
method of Streptavidin –Biotin-Complex were used to 
get the expression of PARP-1. The counting of gingival 
epithelial cells which expressed PARP-1 was done 
under light microscope with 400 times magnification. 
Cells which proved to be positive gave brownish color 
between bluish/greenish epithelial cells. Every reserves 
were examined at 4 different places clockwise 3, 6, 9, and 
12. Each field of vision are examined and counted at two 
places according to 6 and 12 needle using counting room 
and counter. This research used the t-test statistical analysis 
with 95% sensitivity (p < 0.05). To strengthen the image 
of early apoptosis using PARP-1 expression, the DNA 
fragmentation test was performed with electrophoresis gel. 
DNA was purified from epithelial gingiva cultured cells 
using a DNA extraction kit (Stratagene #200600; La Jolla, 
CA). The purified DNA was electrophoresed using a 2% 
agarose gel with ethidium bromide staining.

results 

The results of immunohistochemical examination shows 
that the number of cells expressing PARP-1 is shown in 
table 1. On the induction of Aa serotype-B crude toxin 
shows an increasing number of cells expressing PARP-1 
with an average rating of 48.9, whereas in the control group 
obtained the results of 25.21.

Normality test is done using Kolmogorov-Smirnov test. 
Normal distribution group continued by parametric test  
(t-test) to know the difference in the group with 5% 
significant rate. Table 1 shows that significant difference 
in number of cells which express PARP-1 in gingival 

Kata kunci: Toksin Aggregatibacteractinomycetemcomitans serotype-B, PARP-1, fragmentasi DNA 

Correspondence: Ernie Maduratna Setiawatie, c/o: Departemen Periodonsia, Fakultas Kedokteran Gigi Universitas Airlangga.  
Jl. Mayjend. Prof. Dr. Moestopo 47 Surabaya 60132, Indonesia. E-mail: setiowati_ernie@yahoo.co.id

table 1. Mean, standard deviation, the significance of number 
of cells which express PARP-1 in gingival epithelial 
cells that exposed to A. actinomycetemcomitant 
serotype-B bacterial toxin 

Group N Mean SD Significance
Control 10 25.21 2.01 0.01
Toxin 10 48.9 1.72 0.01


��Setiawati: Crude toxin of Aggregatibacter actinomycetemcomitans serotype-B

epithelial cell that exposed Aa serotype b toxin. In figure 
1 can shown that the results of immunohistochemical 
examination, the gingival epithelium biopsy of mice to 
detect the expression of PARP-1 with a magnification of 
400√.	At	figure	2,	there	are	many	DNA	laddering	which	
indicates the DNA has been fragmented at the intoxicated 
cells. Apoptosis indicated by the fragmentation at 180–200 

basepairs and its multiples. On the control group, there was 
no DNA fragmentation.

discussion 

 Periodontitis, one of the most common human infectious 
diseases, is an acute or chronic infectious condition that 
can result in the inflammatory destruction of periodontal 
tissues such as periodontal ligaments and alveolar bone. 
Among more than 300 species of bacteria in the oral cavity, 
Porphyromonas gingivalis and A. actinomycetemcomitans 
(Aa) are the major periodontopathic bacteria, and several 
virulence factors related to the pathogenesis of periodontitis. 
Therefore, identification of certain virulence factors of 
Aa serotype-B bacteria would aid in the development 
of preventive strategies against periodontal diseases, 
especially agressive periodontitis. 

Apoptosis plays an important role in the homeostasis 
of cells and tissue in response to damage. The process of 
apoptosis/programmed death of cells shows changes in cell 
morphology include chromatin condensation, cell membrane 
shrinkage, the outbreak of nucleus and apoptotic bodies was 
a sign of DNA fragmentation in nucleosom, releasing PARP-
1. Based on these results, it seems that the exposure of Aa 
serotype-B crude toxins can increase the number of PARP-
1 in the cells of the gingival epithelium. This is caused 
by the Aa serotype-B bacterial toxin, both endotoxin and 
exotoxin can cause apoptosis via different paths. Endotoxin 
(lipopolysacharida) through LPS binding protein binds the 
CD14 in membrane cells will activate IP3 receptors that 
activate calcium release from the endoplasmic reticulum. 
LPS also activates TNF alpha which will trigger apoptosis in 
an external way. LPS induces apoptosis signal in fibroblast 
through tumor necrosis factor receptor 1 (TNFR1), thus 

a B

figure 1. Overview of PARP-1 expression in rat gingival epithelial cells using monoclonal antibody against PARP-1 with a 
magnification	of	400√.	A)	control,	B)	the	provision	of	A. actinomycetemcomitant serotype-B bacterial toxin. Red arrow 
shows the positive results of brown spots on the nucleus of gingival epithelial cells, whereas blue arrows indicate a negative 
result of no brown spots on gingival epithelial cell nucleus.

figure 2. DNA fragmentation from electrophoresis gel 
examination. By using marker (100 bp DNA ladder 
Promega) shows DNA laddering at 200 bp and its 
multiples at the first lane.


�� Dent. J. (Maj. Ked. Gigi), Vol. 45. No. 1 March 2012: 39–42

increasing the activity of caspase 3 and caspase 8. Cylolethal 
descending toxin (CDT) from actinomycetemcomitans 
bacteria inhibit epithelial cell growth, CDT bind to GM3 
ganglioside specific receptor in nucleus using the enzyme 
DNA-like a nuclease that will lead to DNA fragmentation 
thus inhibiting cell cycle G0/G1 and G2/M and inhibit 
cell to enter the mitotic phase. The breakdown of DNA 
internucleosome chain is an early sign of apoptosis. The 
breakdown of DNA chain will activate PARP-1 enzyme, 
which is an enzyme that activate DNA repair in the nucleus. 
But if there is excessive activation, PARP-1 will result in 
the loss of NAD+, causing apoptosis.8,9

PARP-1 is an enzyme in the nucleus which always 
present in eukariota. It consists of proteins with a molecular 
weight of 116 kDa. PARP-1 is the most dominant member 
of the poly ADP-ribose polymerases (PARPs) protein in 
the nucleus, representing more than 85%. PARP-1 plays a 
role in DNA repair that suffers injury. In every 1000 bp of 
DNA, there is 1 PARP molecule. If the DNA is damaged, 
there is an increase of 500 times of PARP to bind to the 
broken DNA chain. PARP-1 produces 50–200 Poly ADP-
ribose (PAR) to be given to the histones protein, DNA-
polymerases, topoisomerase, DNA ligase, and transcription 
factors. PARP-1 catalyzes the breakdown of nicotinamide 
adenine dinucleotide (NAD+) into Nicotinamide and ADP 
ribose, subsequently polymerized forming a branch of poly 
ADP-ribose nucleic acids. In basal state, PARP-1 activity 
is very low, but if there are damages to DNA, PARP-1 
will hyperactively break NAD+ to create poly ADP-ribose 
branch, in turn, will generate the histone proteins and 
enzymes that help the DNA repair. At low levels of DNA 
damage, PARP-1 has the function of repairing the DNA. 
But at medium or high level of DNA damage, PARP-1 may 
lead to cell’s death through apoptosis or necrosis. PARP-1 
requires NAD+ to be hydrolyzed and ADP-ribose units. 
PARP-1 that is too active will cause NAD+ depletion, 
which continues to deplete the ATP.10 

In the present study, we demonstrated that crude toxin 
periodontopathic bacteria Aa serotype b increase PARP-1 
expression which early marker of cell death. This cell death 
is due to apoptosis, since of the crude toxin induced DNA 
ladder formation. A. actinomycetemcomitans serotype-B 
have three cytotoxic factors such as leukotoxin, cytolethal 
distending toxin (CDT), and endotoxin LPS which induces 
both cell cycle arrest and apoptosis. Leukotoxin induced 
apoptosis in HL-60 cells, which was consistent with the 
present.11 Furthermore, it has been reported that both 
cell cycle arrest and apoptosis were induced by partially 
purified A. actinomycetemcomitans serotype-B toxin in 
mouse hybridoma cell line HS-72 cells. It is likely that 
A. actinomycetemcomitans serotype-B produces several 
types of toxins which induce different cytotoxic effects 
against mammalian cells. Treatment with the extract 
from the A. actinomycetemcomitans serotype-B induced 
pore formation on the cell membrane, nucleosomal DNA 
ladder formation, and caspase-3 activation.12-14 The DNA 
breakage resulted in the rapid activation of PARP-1. At the 

same time, ATP and NAD+ concentrations decreased and 
nicotinamide accumulated extracellularly. These findings 
collectively indicated the rapid activation and central role of 
PARP in the pathogenesis of periodontitis.15 This research 
showed that the A. actinomycetemcomitant serotype-B 
crude toxin cause DNA fragmentation and increased 
PARP-1 expression in gingival epithelial cells. The author 
recommends providing cytoprotection materials on gingival 
epithelium to promote epithelial cell survival against Aa 
serotype-B crude toxin. Inhibition of PARP-1 may represent 
a novel host response modulatory approach for the therapy 
of periodontitis. In conclusion, the crude toxin exposure 
of A. actinomycetemcomitant serotype-B leads to DNA 
fragmentation and increase PARP-1 expression.

references

 1. Newman MG, Takei N, Klokkevold P, Carranza F. Carranza’ clinical 
periodontology. 10th ed. Philadelpia, WB Saunder; 2006. 168–81, 409.

 2. Daniel HF, Kenneth M, David F, Karen F, Javier F, Cebile N, 
Marie M, John G. A. actinomycetemcomitans and its relationship 
to initiation of localized aggressive periodontitis. J Clin Microbiol 
2007; 45: 3859–69.

 3. Suzuki T, Kobayashi M, Isatsu K, Nisihara T. Mechanisms involved 
in apoptosis of human macrophages induced by lipopolysaccaride 
from Actinobacillus actinomycetemcomitans in the presence of 
cycloheximide. Infect immune 2004; 72: 1856–65. 

 4. K ato S, Na k a sh i m a , Sug i mu r a , Nish i ha r a T, Kowa sh i  Y. 
Actinobacillus actinomycetemcomitans induces apoptosis in human 
monocytic THP-1 cells. Med Microbiol 2005; 54: 293–8.

 5. Lohinai ZJG, Mabley E, Fehér, Marton A, Komjáti K, Szabó C. 
Role of the activation of the nuclear enzyme poly (ADP-Ribose) 
polymerase in the pathogenesis of Periodontitis. J Dent Res 2003; 
82: 987–92.

 6. Gamonal AJ, Gomez M, Silvà A, Gonzalez MA. New knowledge of 
the pathogenesis of periodontal disease. Quintessence Int 2004; 35: 
706–16.

 7. Bosshardt DD, Lang NPThe junctional epithelium: From health to 
disease. J Dent Res 2005; 84: 9–20. 

 8. Bascones A, Gamonal J, Gomez M, Silvà A, Gonzalez M A. New 
knowledge of the pathogenesis of periodontal disease. Quintessence 
Int 2004; 35: 706–16.

 9. Alikhani M, Alikhani Z, Graves DT. Apoptotic effects of LPS on 
fibroblasts are indirectly mediated through TNFR1. J Dent Res 2004; 
83(9): 671-6.

 10. László V, Csaba S. The therapeutic potential of poly (ADP-Ribose) 
polymerase inhibitors. Pharmacol Rev 2002; 54: 375.

 11. Shenker B, Hoffmaster R, Zekavat A, Yamaguchi N. Induction of 
apoptosis in human T cells by Actinobacillus actinomycetemcomitans 
cytolethal distending toxin is a consequence of G2 arrest of the cell 
cycle. J Immune 2001; 167: 435–41.

 12. Yamaguchi N, Kubo C, Masuhiro Y, Lally E, Koga T. Tumor 
necrosis factor alfa enhances Actinobacillus actinomycetemcomitans 
leukotoxin–induced HL-60 cell apoptosis by stimulating lymphocyte 
function associated antigen 1 expression. Infect Immune 2004; 72: 
269–72.

 13. Zhang L, Pelech S, Uitto V. Long-term effect of heat shock protein 
60 from Actinobacillus actinomycetemcomitans on epithelial cell 
viability and mitogen-activated protein kinases. Infect and Immun 
2004; 72: 38–45.

 14. Dirienzo JM, Song M, Wan LS, Ellen RP. Kinetics of KB and HEp-2 
cell responses to an invasive, cytolethal descending toxin–producing 
strain A. actinomycetemcomitans. Oral Micrbiol Immunol 2002; 17: 
245–51.

 15. Lucas H, Bartold PM, Dharmapatni, Holding CA, Haynes DR. 
Inhibition of apoptosis in periodontitis. J Dent Res 2010; 89: 
29–33.